Display of video with motion

ABSTRACT

A method of displaying a video of a scene on a display with reduced motion blur includes: providing the video of a scene having first subframes that have a first input rate and second subframes that have a second input rate, wherein the first subframes correspond to a first region of the display and the second subframes correspond to a second region of the display; and selectively providing the first and second subframes to corresponding regions in the display, and providing the first region of the display with a first update rate and the second region of the display with a second update rate, wherein the first update rate is greater than the second update rate, so that the displayed image has reduced motion blur.

CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a continuation of U.S. application Ser. No.12/402,577, filed Mar. 12, 2009, which is incorporated herein byreference in its entirety.

FIELD

The disclosure pertains to the display of video images. Morespecifically the invention pertains to an improved method for display ofvideo images where rapid motion is present.

BACKGROUND

Digital display of videos of scenes is a useful and commonly-practicedtechnique. Videos typically include a series of individual frames at aselected frame rate, e.g. 24 frames per second (fps), and each framerepresents light accumulated for a selected exposure time, e.g. 41.7 ms(= 1/24 sec.). Each frame comprises a two-dimensional array ofindividual pixels.

Scenes, and thus videos of scenes, can contain global motion or localmotion. Global motion refers to relative motion between an image capturedevice and the scene being imaged, such as when a camera is panningacross a scene. Local motion refers to motion of objects within thescene, such as a ball being thrown. When a video contains either globalmotion or local motion rapid enough to cause features within the imageto move across more than one pixel during the exposure time of a frame,image quality can be degraded by blurring and smearing of the image. Itis therefore desirable to reduce blur of rapidly moving objects in videoframes to improve image quality.

Typically higher quality video such as high definition or HD video(720p, 1080i or 1080p) is captured at a higher frame rate, 30 fps or 60fps, to reduce the blurring associated with motion during capture.However, when rapid motion is present in a scene, such as a ball beingthrown in a sporting event, the image of the ball can be noticeablyblurred even at 60 fps. Very fast frame rates can be used to reduce blurand improve video image quality of rapidly moving objects. However, asthe frame rate is increased, the amount of image data increasesproportionately, which can result in data rates too high for datastorage, image processing or data transmission bandwidth in imagingsystems such as a consumer video camera, a digital camera or a cellphone camera.

One factor in blur of frames on a display is the response time of thedisplay, the time required for the light from a particular pixel tochange from one value to the next. Electroluminescent (EL) displays,such as organic light emitting diode (OLED) displays, employ materialsthat have response times that are measured in microseconds (Samsungreports a response time for their active matrix OLED display of 10microseconds on their website:http://www.samsungsdi.com/contents/en/product/oled/type01.html). As usedherein, the “update rate” of a display is the rate at which thecommanded light output of the display is changed. For example, aconventional 24 fps display has a 24 Hz update rate: each time a newframe is received, the display is commanded to output lightcorresponding to that frame. The update rate is limited by the responsetime of the display. The low response times of EL displays thus makethem theoretically capable of achieving very high update rates

However, limitations in the drive electronics of EL displays, the imagetransmission systems and the image processing system within the videocapture devices such as consumer video cameras, a digital camera or acell phone camera, do not permit update rates above approximately 30 Hzto be supported at higher resolutions. If the capture systems supportedvery high frame rate with high resolution video capture, such videowould require large amounts of bandwidth for transmission and specialelectronic drives for the display.

Video compression techniques such as described in U.S. Pat. Nos.6,931,065 and 5,969,764 ('764) are useful in reducing the transmissionbandwidth of images, partly based on detecting changes (mean absolutedifferences) between frames and avoiding the transmission of duplicateimage data for multiple frames when the scene is not changing, to reducedata transmission bandwidth and data storage requirements. As such, thetechnique described in the '764 patent effectively reduces the datatransmission rate for regions of the scene that are not changing andkeeps the original data transmission rate for areas where motion ispresent. However, on decompression, video images are reconstructed fordisplay at a constant update rate. As such, this method does not changethe display update rate.

U.S. Pat. No. 5,389,965 describes a variable frame rate system for videocommunication. This system permits the user to select the frame rateused to deliver the desired image quality in a mobile communicationenvironment where data transmission bit rates are limited. Slow framerates are used to deliver higher resolution images at the expense ofjerky motion. Faster frame rates deliver smoother motion with lowerresolution images. However, the frame rate is constant within the framerate selected by the user so as such, the frame rate does not change inresponse to the motion present in the image being displayed. Further,Cok in commonly-assigned U.S. Pat. No. 7,242,850 provides a method forproviding a variable frame rate in a display system where the frame rateis dependent upon the motion within the scene as it was originallycaptured. This patent discusses changing the rate at which entire framesare delivered within the video sequence and requires the system becapable of adapting to the increased bandwidth required to deliver thehigher frame rates during rapid motion.

Within the display literature, it is known to receive video at 60 fpsand to up-convert the input video to 120 fps to provide an update rateof 120 Hz to display the video without artifacts. For example, Shin etal. in a paper entitled “Motion Interpolation Performance of 120 HzDisplay Systems” published in the SID '08 Digest (2008) discussesproducing 120 fps video using interpolation to improve motion blur andjudder. By upconverting the input signal within the display device, thevideo can be displayed at a faster frame rate. However, the display anddrivers must be designed to support relatively high-resolution updatesat a full 120 Hz. Doubling the rate of such drivers from 60 Hz to 120 Hzcan be expensive. Furthermore, in displays such as OLED displays, whichtypically have a high capacitance and have drive lines with asignificant resistance, accurately updating information at 120 Hz andmaintaining the full bit depth of the display can present a significantchallenge. Further, upconversion to 120 fps does not recognize theproblem that significant image blur can be introduced during motioncapture, and this motion blur is not reduced through these schemes. Thisis described in Klompenhouwer (2007), “Dynamic Resolution: Motion Blurfrom Display and Camera,” SID 2007 Digest. As described in this paper,it is important that the image be provided with a short temporalaperture as well as it is important that the display provide a shorttemporal aperture.

Hekstra et al., in U.S. Patent Application Publication No. 2005/0168492,disclose reducing image blur by decreasing the hold time of the display.Decreasing the hold time increases the update rate, as the display isset to output light corresponding to an image at the frame rate, e.g. 60Hz, and set to output no light at 60 Hz approximately 180 degrees out ofphase with the first updates, resulting in a total update rate of 120Hz. According to this scheme, an input video can be analyzed todetermine the rate of motion and the hold time of a display can becontrolled based upon the determined rate of motion. However, thismethod requires an estimation of the rate of motion directly from thevideo, which is typically input at 60 fps. Since this video is capturedat this rate, it has likely undergone motion blur during capture andthis blurring can make the estimation of motion difficult. Therefore,the resulting video will contain artifacts due to errors in estimationof the rate of motion. Further, this method ignores the fact thatsignificant image blur can be introduced during motion capture, and thismotion blur is not reduced through this method. Consequently, thereexists a need for an improved method for the display of video image datafor rapidly moving objects in a way that does not substantially increasethe amount of video image data to be processed or substantially increasethe bandwidth of the display drivers.

SUMMARY

This need is met by a method of displaying a video of a scene on adisplay with reduced motion blur comprising:

(a) providing the video of a scene having first subframes that have afirst input rate and second subframes that have a second input rate,wherein the first subframes correspond to a first region of the displayand the second subframes correspond to a second region of the display;and

(b) selectively providing the first and second subframes tocorresponding regions in the display, and providing the first region ofthe display with a first update rate and the second region of thedisplay with a second update rate, wherein the first update rate isgreater than the second update rate, so that the displayed image hasreduced motion blur.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an illustration of a display showing an embodiment of theinvention;

FIG. 2 is a flow chart of a method that constitutes a further embodimentof the invention;

FIG. 3 is a schematic diagram of the timing of display updates fordifferent regions within the displayed image in another embodiment ofthe invention;

FIG. 4 is a schematic diagram of the timing of display updates fordifferent regions within the displayed image in yet another embodimentof the invention;

FIG. 5 is a schematic diagram of a display system useful in practicingthe present invention;

FIG. 6 is a timing diagram illustrating the timing of first and secondsubframes according to one embodiment of the present invention;

FIG. 7 is an illustration of an active matrix EL circuit layout usefulin practicing the present invention;

FIG. 8 is a flow chart illustrating the steps that constitute a furtherembodiment of the present invention;

FIG. 9 is a flow chart illustrating the steps that constitute a furtherembodiment of the present invention;

FIG. 10 is a timing diagram illustrating the timing of first and secondsubframes according to an embodiment of the present invention;

FIG. 11 provides timing diagrams illustrating light emission of thedisplay in response to first and second subframes according to anembodiment of the present invention;

FIG. 12 is a flow chart illustrating the steps that constitute a furtherembodiment of the present invention;

FIG. 13 is a flow chart illustrating the steps that constitute a furtherembodiment of the present invention;

FIG. 14 is an illustration of motion vectors according to an embodimentof the present invention; and

FIG. 15 is an illustration of phase relationships according to anembodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The disclosure provides a method to reduce motion blur in a displayedvideo image by providing an increased rate of image information to theregions of the display that are associated with rapid motion in theimage. FIG. 1 shows an illustration of a display 100 showing an image ofa person fencing wherein the fencer's arm and the foil are movingrapidly and as a result, those regions of the displayed video image areblurred. In an embodiment of the invention, a video signal of the sceneis provided to the display. This video signal has first subframes thathave a first input rate I₁ and second subframes that have a second inputrate I₂. The input rates are measured in Hz. First and second subframeinput times J₁, J₂, measured in seconds, are then defined as:J ₁=1/I ₁ ; J ₂=1/I ₂.

The first subframes provide information corresponding to a first regionof the display, which corresponds to a region for displaying fastmotion, for example, corresponding to the first region 120 of thedisplay. The first subframes have a first input rate, for example 120Hz. The second subframes correspond to a second region of the display,for example, the entire display or the regions without fast motion 110a, 110 b. These second subframes can, for example, have a second inputrate of 60 Hz.

In this system, the first and second subframes are selectively providedto corresponding regions of the display 100. The first region 120 of thedisplay 100 is then updated with a first update rate and the secondregion of the display is updated with a second update rate wherein thefirst update rate is greater than the second update rate. For example,the first update rate can be equal to the total input rate for the firstregion and the second update rate can be equal to the second input rate.Therefore, the update rate of region 120 is increased where the fencer'sarm and the foil are located in the image to reduce blur caused by therapid motion. In contrast, the update rate for regions 110 a and 110 bis slower where the motion of the fencer's body is relatively slow andthe image is not blurred.

A “region” is a spatial area of the display. A region can include all ora subset of the subpixels or EL emitters within a spatial area of thedisplay. “Update rate” is the rate at which image data or video signalsare changed and provided to the subpixels or EL emitters within aspatial area of the display. “Refresh rate” refers to the rate at whichsubpixels or EL emitters within an area of the display are addressed.The update rate and refresh rate are equal only when the image data orvideo signals to the display are changed every time an area of thedisplay is addressed. However, a spatial region of the display can berefreshed multiple times with the same input data or video signal andtherefore the refresh rate can be greater than the update rate. Thefirst and second regions can each include multiple spatial areas. Thefirst and second regions can intersect spatially, and the first regioncan be a subset of the second region.

In the illustration shown in FIG. 1, the region with the faster updaterate is in the form of entire rows on the display 100 so the region 120is shown as a rectangle that goes from one edge to the other edge of thedisplay 100. However within the scope of the invention, there can bemore than one region with a faster update rate and the region(s) withthe faster update rate can be other shapes as well, as required toencompass the regions of the image which contain rapid motion so that afaster update rate can be used to reduce motion blur. The region(s) withthe slower update rate encompass the remainder of the display area otherthan that which is contained in the region(s) with the faster updaterate.

FIG. 2 shows a flow diagram of the method for displaying the video imagedata according to one embodiment of the invention. In Step 200, thevideo image data is provided to the display in the form of subframeswherein the image data for subframes with rapid motion is updated at afaster rate than the subframes with slow or no motion. Subframes withlocally varying update rates that relate to the speed of motion presentcan be provided as captured with a locally varying capture rate or ascomputer-generated images with a locally varying rendering rate. In Step210, the video image data for first subframes is provided to a firstregion on the display and in Step 220 video image data for secondsubframes is provided to a second region of the display. In Step 215,the first region of the display is updated at a first update rate and inStep 225, the second region of the display is updated at a second updaterate. The update rate of the first region of the display is faster thanthe update rate of the second region of the display because the firstregion of the display is associated with the first subframes of thevideo image, which contain areas of rapid motion. In Step 230, the userobserves a displayed video image with reduced motion blur that includesthe combined first and second regions of the display.

FIG. 3 shows an illustration of an example of the relative timing of theupdates of the different regions of the display in an embodiment of theinvention. In this example, the regions of the display with rapid motionhave an update rate that is 3.times. faster than the regions with slowor no motion as exemplified by the 7 pulses 20 a, 20 b, 20 c, 20 d, 20e, 20 f, 20 g signifying the initiation of an update for the regionswith rapid motion as compared to the 3 pulses 10 a, 10 b, 10 csignifying the initiation of an update for the regions with slow or nomotion within the same time interval. By increasing the update rate forthe regions with rapid motion, the regions with rapid motion have ⅓ theamount of motion blur that would have been present if the update ratewas the same as the regions with slow or no motion.

FIG. 4 shows an illustration of another example of the relative timingof the updates of the different regions of the display in anotherembodiment of the invention. In this example, the update rate, specifiedin updates per unit time for the regions with rapid motion, changes asthe motion present in the region speeds up and slows down. Specifically,FIG. 4 shows that the 9 pulses 30 a, 30 b, 30 c, 30 d, 30 e, 30 f, 30 g,30 h, 30 i signifying the initiation of an update for the regions withrapid motion are not at a constant spacing as a function of time, andtherefore these regions do not have a constant update rate. In contrast,the update rate for the regions with slow or no motion is slower thanthe update rate for the regions with rapid motion and the update ratefor the regions with slow or no motion remains constant as indicated bythe three equal-distant pulses 10 a, 10 b, 10 c.

In general, increasing the update rate of regions of the display resultsin an overall increase in the bit rate or bandwidth required to displaythe video image data. Increasing the bit rate or bandwidth is acceptablein some displays, but in many display systems the bit rate or bandwidthis limited. Consequently, in an additional embodiment of the invention,increases in the update rate of or the size of the regions with rapidmotion can be accompanied by decreases in the update rate of otherregions of the display, specifically the regions with very slow or nomotion. This balancing of increased update rate for some regions anddecreased update rate for other regions enables the image quality of theregions of the display with rapid motion to be improved and the overallbit rate or bandwidth required in the display system to be maintained orreduced. In one embodiment of the invention, the balancing of thechanges in update rate are done based on the relative areas of theregions associated with rapid motion compared to the regions associatedwith slow or no motion. For example, a small area of rapid motion in thevideo image would require a large increase in update rate to reduce themotion blur. This increase in update rate for the small area of theimage would be balanced by a small decrease in update rate for a muchlarger area of the image (or even the entire remainder of the image)where there is slow or no motion present.

Referring to FIG. 5, in a first detailed embodiment of the presentinvention, the display system includes an EL (electroluminescent)display. A display system 600 includes a controller 602 for receiving avideo signal 604. This video signal includes first subframes that have afirst input rate and second subframes that have a second input rate. Thefirst subframes correspond to a first region of the display 634 and thesecond subframes correspond to a second region of the display 630. Inthis embodiment, the first region of the display 634 is a subset of thesecond region of the display 630. The first region of the display 634has a corresponding total input rate, which is greater than or equal tothe greater of the first input rate and the second input rate butgreater than the second input rate. Further, the first update rate isgreater than or equal to the total input rate.

The total input rate I_(t) is the rate, in Hz, at which new informationis provided to the first region of the display. When the first andsecond regions overlap wholly or partially, the total input rate for theoverlapping area is constrained as follows:min(I ₁ ,I ₂)≦I _(t) ≦I ₁ +I ₂

That is, the total input rate is less than or equal to the sum of thefirst input rate and the second input rate but equal to or larger thanthe smaller of the first or second input rates. The exact value of thetotal input rate when these rates are periodic depends on I₁ and I₂ anda phase relationship Φ between the first and second subframes.

In some embodiments, I₁=nI₂ for some integer n>1. Phase relationship Φcan then be expressed in degrees or radians by dividing the time from asecond subframe to the next first subframe by J₂ and multiplying by360°. When Φ=0°, first and second subframes are in phase. Every secondsubframe thus arrives at the same time as a first subframe. In this casethe total input rate is equal to the higher of the first and secondinput rates. When Φ≠0°, the first and second subframes are out of phase,meaning every second subframe arrives at a different time than everyfirst subframe. In this case the total input rate is equal to the sum ofthe first and second input rates. For example, FIG. 15 shows threetiming diagrams 340, 345, 350. Timing diagram 340 depicts the initiationof the second subframes as signals 360 a, 360 b, 360 c. Timing diagram345 depicts initiation of first subframes 370 a through 370 g when Φ=0°.As such, the total input rate is equal to the first input rate. Timingdiagram 350 depicts initiation of first subframes 380 a through 380 gwhen Φ=180°. In this example, the total input rate is equal to the sumof the first and second input rate.

In some embodiments, I₁≠nI₂ for all integers n>1. The first and secondinput rates thus beat together, andI _(t) =I ₁ +I ₂−(I ₁ −I ₂), for I ₁ >I ₂.That is, the total input rate is equal to the number of times per secondeither the first or second region is updated, since the total input ratecorresponds to the overlap between the two regions, minus the number oftimes per second the two regions update simultaneously (which is thebeat frequency term I₁−I₂). When the regions update simultaneously, theoverlapping area can be updated with data from either region, as the twohave equivalent content.

Subframes can also be delivered aperiodically. For example, the firstsubframes can each require different time intervals, or the firstsubframes can be delivered within the period other than that in whichthe second subframes are delivered. The total input rate, whichcorresponds to the first region, is always greater than the second inputrate. For example, when the second subframe corresponds to the entiredisplay, the first subframes are stored to provide data intermediate tothe second subframes within the temporal domain, providing a total inputrate for the first region of 180 Hz when the second subframes aredelivered at a rate of 60 Hz and the first subframes are delivered at arate of 120 Hz between successive second subframes (Φ≠0°) Referring backto FIG. 1, when the second subframe corresponds to the regions withoutfast motion 110 a and 110 b, the first subframes can be recordedsynchronously with the second subframes with Φ≠0°, providing a totalinput rate for the first region of 120 Hz. As such, first region 120containing the fencer's arm is provided with a total input rate that isgreater than the input rate for the remainder 110 a, 110 b of the scene.

In this first detailed embodiment, the video signal comprises a temporalsequence as shown in FIG. 6. The temporal sequence includes firstsubframes 700 a, 700 b, 700 c, 700 d, 700 e and second subframes 702 a,702 b. In this example, the second subframes include data correspondingto the entire display to be updated by the input video signal andinclude each row of data, provided in a time sequential order. The firstsubframes 700 a, 700 b, 700 c, 700 d, and 700 e include datacorresponding to the first region of the display, which fully overlapand therefore are a subset of the second region as they correspond to aregion within the display. The first regions represent regions of thedisplay that correspond to regions of the original scene in which rapidmotion occurred. In this example, the first subframes include a timesequence of data corresponding to a sequence of row information. Thevideo signal, as shown, also includes region location data 704 a, 704 b,704 c, 704 d, and 704 e associated with the first subframes 700 a, 700b, 700 c, 700 d, and 700 e. This region location data 704 a, 704 b, 704c, 704 d, and 704 e defines the location of the first region for eachfirst subframe with respect to the second region, the display, or thecapture medium. In this example, where the second region corresponds tothe entire display and the first region corresponds to a rectangularportion of the display, the region location data 704 a, 704 b, 704 c,704 d, and 704 e can define the location of the top left corner andbottom right corner of the first region within the second region. Asshown in this example, the number of first subframes are not required tobe the same with respect to the number of second subframes. Further theregion location data 704 a, 704 b, 704 c, 704 d, and 704 e can beprovided for each first subframe 700 a, 700 b, 700 c, 700 d, 700 e andcan precede the first subframe of data to provide instructions on theportion of the display to be updated, such that it is not necessary tostore data before receiving the first subframes 704 a, 704 b, 704 c, 704d, and 704 e.

Referring to FIG. 8, and also to FIGS. 5 and 7, in an embodiment of thepresent invention, the controller 602 receives a video signal 604 inStep 42. As the video signal 604 is received in Step 42, the controller602 determines if the subframe is a first or a second subframe in Step44. This can be done, for example, based upon the presence or absence ofregion location data as the region location data is required only forfirst subframes. If a second subframe 702 a is received, the controller602 provides a control signal 606 to a first row driver 608 to select afirst row of electroluminescent (EL) emitters in the display in Step 46beginning at the top of the display. The controller 602 then providesdrive signals 610 to column drivers 612 for each EL element within theselected row of EL emitters in Step 48, which provide a voltage to theEL elements within the row. The controller 602 then provides a signal tothe first row drivers 608 to deselect the row of EL emitters in Step 50and provides a signal to the column driver 612 to remove the data signalfrom data lines 716 of the display in Step 52. The controller 602 thendetermines if all rows of the display have been updated in Step 54. Ifnot, the controller 602 provides a signal to the first row driver 608 toselect the subsequent row of the display in Step 56 and repeats steps48, 50, 52, and 54. If the controller 602 determines that all of therows have been updated in Step 54, the controller 602 continues toreceive the video signal in Step 42 and determine if the next subframeis a first or second subframe in Step 44.

Upon completing the update of the display in response to the secondsubframe 702 a, 702 b, it then receives a first subframe 700 a. Upondetermining the presence of a first subframe in Step 44, the controller602 determines the region location based upon the region location data704 a, 704 b, 704 c, 704 d, 704 e in Step 58. It then processes the datawithin the first subframe in Step 60 to hide the boundary between thefirst and second subframes, as will be discussed below, and commands thefirst row driver to select the first row within the first regioncorresponding to the first subframe in Step 62. The controller 602 thenprovides a control signal to the column driver to provide data to eachactive matrix circuit of each EL emitter in Step 64. The controller 602commands the first row driver to deselect the row in Step 66 and thecolumn driver to remove the data signal from the data line in Step 68.The controller 602 then determines if all rows in the region have beenupdated (Step 70). If not, it causes a subsequent row to be selected(Step 72) and repeats steps 64, 66, 68 and 70. Once all rows in theregion have been updated, the controller 602 continues receiving thevideo signal in Step 42 and determining if the next subframe is a firstor second subframe in Step 44.

The first row driver 608 can quickly select the first row within thefirst region of the display by sequencing the first row driver 608through the rows of the display or by commanding the first row driver608 to randomly access a row. For the random access case, arandom-access gate driver such as that set forth in commonly-assignedU.S. Patent Application Publication No. 2007/0229408 by Primerano, canbe used. This random-access gate driver receives an address signal andincludes a random access decoder for activating a gate linecorresponding to the address signal. According to the present invention,the number of the first row within the first region of the display canbe provided to the gate driver as the address signal.

As indicated by the signal depicted in FIG. 6, the controller 602 canthen continue this process by receiving another set of region locationdata 704 b for first subframe 700 b. Subframe 700 b is then processedand presented using the method depicted in FIG. 8. Once these two firstsubframes have been displayed, the following second of the secondsubframes 702 b is received Step 42 by the controller 602, whichcommands the first row driver 608 to initially select the first row ofEL emitters in the display and then continues to provide drive signalsto the column driver 612 and command the first row driver 608 tosequentially select each of the rows of EL emitters within the displayaccording to the method of FIG. 8. First subframes 704 c, 704 d, and 704e are then received and processed, according to the method of FIG. 8. Inthis way, the first regions of the display are updated a total of 7times while the second regions are updated only 2 times during the sameperiod.

To successfully provide such an image on the display, the EL displayshown in FIG. 5 can preferably have certain characteristics to enablethe periodic and non-sequential update of portions of the second displayregions. To understand these characteristics, it is useful to understandthe active matrix structure commonly employed in an active matrix ELdisplay as depicted in FIG. 7. This figure shows a portion 710 of anactive matrix backplane useful in an EL display of the present inventionthat includes select lines 712. These lines carry a signal from thefirst row driver 608 to the circuit at each EL element in the display,with each row of EL emitters typically sharing the same select line 712.When a high voltage is placed on this select line 712, the gate of theselect TFT 714 is opened. This permits a signal to be carried from thedata line 716 as provided by the column driver 612 to a capacitor 718.Once this signal, typically a voltage signal, is provided by the dataline to the capacitor 718, the first row driver 608 deselects this rowof EL emitters by placing an inverse logic signal, typically a lowvoltage, on the select line 712. This deselection precludes thecapacitor 718 from receiving additional current or voltage signalsthrough the data line 716 until the select TFT receives anotherselection signal. A capacitor line 711 can also be provided andconnected to the other side of the capacitor 718 to provide a referencevoltage. Once this capacitor 718 is charged, it provides a voltage tothe power TFT 720, opening this TFT and permitting current to flow froma power line 722 to an electrode 724 of the EL element, causing the ELelement to produce light.

The amount of current that is permitted to flow from the power line 722to the electrode 724 is proportional to the voltage stored on thecapacitor 718. Further, the luminance output of the EL element isproportional to this current and therefore to the voltage on thecapacitor 718. In an ideal system, the voltage on the capacitor 718would remain constant indefinitely unless the row driver 608 provided aselect signal on the select line 712 and the column driver 612 on dataline 716 provided a different data signal. Unfortunately, the dielectricin typical capacitors 718 is far from ideal and leakage currents occur,which reduce the voltage of the capacitor 718 as a function of time.Within the system of this example, this implies that the non-overlappingregions of the first and second region, which are updated lessfrequently will become lower in luminance as a function of time, and theareas that are updated more frequently will lose less luminance.Therefore a sudden gradation in luminance can exist between theboundaries of the first and second regions, which can produce a visibleand undesirable artifact.

The visibility of artifacts can be reduced according to the presentinvention. Capacitor 718 can be sized to hold enough charge that aluminance loss of less than or equal to four percent occurs betweenupdates of the second regions of the display. Alternatively, the signalfor each update of the first region of the display can be reduced tobring the respective luminances of the first and second regions within aselected percentage of each other, e.g. four percent. In anotheralternative, the luminances of those pixels in the first region whichare near the boundary between the first and second region are reduced toprovide a gradual gradient in luminance between the first and secondregions, thereby making this transition much less visible. As such, themethod further includes modifying selected pixel values in the firstsubframe or second subframe to reduce the visibility of boundariesbetween the first region and the second region in the displayed video.

The first subframes and their associated image data, can be compressedin a number of ways to reduce the bandwidth required to transmit them.For example, it is well known to compress motion data through the use ofmotion vectors, to encode the motion of objects within a scene ratherthan repeating image data for multiple frames of image data. Thereforeit can be desirable for at least the first subframes to include motionvectors, which can be decoded. A motion vector is a mathematicaldescription of the motion of objects or features within a region withinthe image. For example, in an image region 300 as shown in FIG. 14, anobject in motion can move from location 310 in a first frame to anotherlocation 320 in a second frame due to the relative motion of the objectbetween the times of capture of the first and second frames. The motionvector 330 describes the motion of the object so that the location ofthe object 320 in the second frame can be specified in terms ofknowledge of the location of the object 310 in the first frame and thedirection and length of the motion vector 330. Thus this method cansubstantially reduce the bandwidth required to encode the informationfor moving objects. In such systems, the controller can require accessto a memory 624 to store previous subframes of image data to which themotion vectors can be applied to determine the image data to bedisplayed.

Referring to FIG. 5, it can be useful for the display to provide memory624, permitting only the rows of the display that are to be updated tobe physically refreshed with new information. It can also be useful torefresh the entire display, by selecting and providing each line of thedisplay with information without updating the information to all of theEL emitters in the display. In such a display system, at least thesecond subframes and additionally the first subframes can be stored inmemory 624 either within or accessible by the controller 602. In thissystem, the controller 602 commands each and every row of the ELemitters in the display at a rate that is at least as high as the firstinput rate to be refreshed. However, the EL emitters within the secondregion are refreshed with data from memory 624 and are therefore updatedwith new information at a rate equal to the second input rate. In suchsystems, the update rate within the first regions of the display ishigher than the input rate of the second subframes as these secondsubframes are stored in memory 624 and used to refresh the displaymultiple times during which the first subframes are used to update thefirst regions of the display at a rate that is higher than the secondinput rate. As such, the method includes storing the video of a scene inmemory 624 and the display can be simply refreshed by reading each datapoint from memory 624 and addressing the display with the informationthat is present within the memory. Within this embodiment, the presentinvention provides a method for updating the memory 624, which is thenused to refresh the display. However, because the first regions areupdated in memory 624 more frequently than the second regions, the firstupdate rate of the first regions is faster than the second update rateof the second regions

FIG. 9 shows a flow chart for updating the memory 624 according to thisembodiment. As shown in FIG. 9, the video signal is received by thecontroller in Step 82. The controller 602 determines if the subframebeing input is a first or second subframe in Step 84. If it is a secondsubframe, as depicted in FIG. 6, the entire second subframe is writtento memory 624 in Step 86 to provide a full frame buffer for refreshingthe display. The controller 602 then continues to receive the videosignal in Step 82 and in Step 84 determines if the next subframe is afirst or second subframe. As depicted in FIG. 6, this subframe is afirst subframe. In response to the first subframe, the controller 602then receives the region location information to determine the regionlocation in Step 88. The data in the first subframe is then processed inStep 90 to hide the region boundary. A region is then selected in memory624 corresponding to the region of this first subframe in Step 92. Datais then written into this memory at the location corresponding to theregion of this first subframe in step 94. Again, an additional videosignal is received Step 82). As this memory is continuously updated, thecontroller can sequentially read each line from the memory andsequentially refresh each row of the display with the information fromwithin the memory.

In the previous example, the first region is a subset of the secondregion of the display. In another example, the first and second regionsdo not overlap. In this example, the method of displaying the video of ascene on a display with reduced motion blur includes providing video ofa scene having first subframes that have a first input rate and secondsubframes that have a second input rate, wherein the first input rate isgreater than the second input rate. The first and second subframes areprovided to the corresponding regions in the display, wherein the firstregion of the display has a first update rate and the second region ofthe display has a second update rate wherein the first update rate isgreater than the second update rate. Further, the first update is equalto the first input rate enabling the first update rate to be greaterthan the second update rate. Referring again to FIG. 1, the first region120 is represented by first subframes. The second regions 110 a, 110 bare represented by second subframes and the first region 120 and secondregions 110 a, 110 b do not overlap in this example.

In a third example, the method of displaying a video of a scene includesproviding video of a scene having first subframes that have a firstinput rate and second subframes that have a second input rate, whereinthe first subframes correspond to a first region of the display and thesecond subframes correspond to a second region of the display. Themethod then selectively provides the first and second subframes tocorresponding regions in the display, the first region of the displayhaving a first update rate and the second region of the display having asecond update rate. In this example, the first update rate is greaterthan the second update rate and the first update rate is greater thanthe first input rate. This can be achieved by a number of methods. Inone particular embodiment, the display system shown in FIG. 5 canadditionally include a second row driver 620, which is controlled by asignal 622 from the controller 602. This second row driver 620 canattach to the same select lines 712 as the first row driver 608 and canpermit the select TFTs 714 to be activated twice within an update cycle.However, during the time that the second row driver 620 opens the selectTFTs on a row, the column driver 612 can be commanded by the controller602 to serve as a current sink, permitting the voltage to be removedfrom the capacitors 718 and deactivating the EL emitters in a row of thedisplay. The second row driver 620 can deactivate the rows in the firstregion of the display without deactivating the rows of EL emitters inthe second region of the display.

FIG. 10 shows a timing diagram 746 for a row of EL emitters within thefirst region and a corresponding timing diagram 748 for a row of ELemitters within the second region of the display. As shown in thisfigure, the timing diagram 746 for rows of EL emitters within the firstregion depicts the fact that the EL emitters in the row are activated 9times to provide 9 intervals 740 a, 740 b, 740 c, 740 d, 740 e, 740 f,740 g, 740 h, 740 i during which the EL emitters are active. Within thisexample, the input rate is adjusted such that the EL emitters within therow are activated at a rate that matches the input rate of the firstsubframes within the first regions. This first activation rate can beachieved by synchronizing the select signal provided by the first rowdriver 608 with the input rate of the first subframes within the videosignal 604. However, the update rate of the EL emitters within the firstregion is further increased as the second row driver 620 provides aselect signal to activate the select TFTs 714 within the intervalbetween the time that the first row driver 608 provides a select signalin response to subsequent first subframes in the video signal 604 whichcorrespond to the spatial location of this row of EL emitters and thecolumn driver 612 sinks the current from the capacitors 718 todeactivate the EL emitters within the first region of the display withinthis time interval. Therefore, as shown in the timing diagram 746,although each EL element within the row of the first region is activatedin response to a first subframe within the video signal, each EL elementwithin the row of the first region is deactivated, providing 9deactivation intervals 742 a, 742 b, 742 c, 742 d, 742 e, 742 f, 742 g,742 h, 742 i with each deactivation interval occurring between the timethat the video signal 604 provides a portion of the first subframecorresponding to this row of EL elements. As such, the update rate foreach row of EL element within the first region is twice the input rateof the first subframes. By decreasing the on-time (i.e., the time thateach EL element is active in response to an input signal) of each ELelement within the first region of the display, motion blur within thisregion is further reduced.

In this example, EL elements within the second region can have an updaterate that matches the input rate of the second subframes within thesecond region. The timing diagram 748 depicts such an example.Specifically, the timing diagram 748 for rows of EL emitters within thesecond region depicts the fact that the EL emitters in the row areactivated 3 times to provide 3 intervals 744 a, 744 b, 744 c duringwhich the EL emitters within this row of the second region are active.Since these EL emitters are only activated 3 times in the same intervalas the EL emitters within the first region as depicted in timing diagram746, the first input rate for the first subframes is higher than thesecond input rate for the second subframes. However, as shown, theupdate rate of the EL emitters within the row is equal to the input rateof the second subframes. That is, the EL emitters within the row of thesecond region are active during the entire time between receivingportions of the second subframe of the video signal corresponding to therow of EL elements.

In this example, it can be noted that the on-time for the EL elementswithin the first region is shorter than the on-time for the EL elementswithin the second region. That is, the EL emitters within the first andsecond regions of the display have a different duty cycle, wherein theduty cycle refers to the ratio of the on-time to the time betweenactivations of the EL elements. Therefore, luminance, which isintegrated over space and time, can be lower within the first regionthan the second region, unless the video signal for one of these regionsis adjusted. Therefore, within a further embodiment of the invention,the video signal is adjusted to increase the instantaneous luminancewithin the first region or decrease the instantaneous luminance withinthe second region to adjust for a difference in EL element on-time.

In the example depicted using FIG. 10, the input rate for the firstsubframes is higher than the input rate for the second subframes and theupdate rate within the first region is higher than the input rate of thefirst subframes. However, it is only required that the update ratewithin the first region be higher than the update rate within the secondregion. In fact, it can be desirable to provide first subframes andsecond subframes at equal input rates but to provide an update rate inthe first region that is higher than the update rate in the secondregion. However, it is required that the video signal containsinformation, such as timing information for the first subframes, topermit the display to distinguish the first subframes from the secondsubframes. In each of the previous examples, the first subframes aredefined by the presence of additional image data to allow the firstregion of the display to be updated at a rate that is higher than thesecond region of the display. This additional image data is providedthrough the presence of additional subframes.

In another example, a capture device or a graphics rendering system canprovide first and second subframes within a first input rate that isequal to the second input rate, but define the first subframes to reducethe amount of data required. In this example, the capture device orgraphics rendering system can determine the motion within differentregions of the video and define first and second subframes by includingmotion rate indicators within the video. The motion rate indicators aredependent upon the rate of motion of objects within the subframes. Forexample, the motion rate indicators can include exposure time indicatorscorresponding to the integration time that was required to capture orrender each subframe without motion blur, e.g. 16 ms or 8 ms. The motionrate indicators can also include capture rate indicators correspondingto the frequency of scene captures per unit time, e.g. 60 Hz or 120 Hz.The motion rate indicators can also include a motion map indicating, foreach pixel or region of each frame of the video of the scene, how thatpixel or region's image data moves between consecutive frames or withrespect to a previous frame. In addition, motion maps can be producedfrom motion vectors as is well known in the art. These motion rateindicators can be provided for each subframe, for only the firstsubframes or for each pixel. Further, the motion rate indicator caninclude different resolutions of motion rate information. The rateindicator can be a single bit, which together with region location dataindicates the presence and location of first subframes. Alternatively,only the region location data for the first subframes can be providedand the first subframes defined by this region location data can have amotion rate indicator that indicates a relatively higher rate of motionwithin the first subframes than in the second subframes. The motion rateindicator can further include several bits, allowing furtherspecification of the relative or absolute rate of motion within one ormore first regions within the video.

FIG. 11 shows three timing diagrams 750, 752, 754 for an example systemhaving equal first and second data rates with a motion rate indicator todefine the first and second subframes. In this system, the video can beprovided by a video signal including first and second subframes, wherethe first subframes include a motion rate indicator. In this example,the times 756 a, 756 b, 756 c, 756 d indicate the times that a selectsignal and data is provided to a row for four sequential subframes.

A timing diagram 750 is shown for a second subframe and two additionaltiming diagrams 752, 754 are shown for two first subframes havingdifferent rate indicators. The timing diagram 752 has a motion rateindicator indicating that the motion within this first subframe isfaster than the motion within the second subframe having the timingdiagram 750. However, the timing diagram 754 has a motion rateindicator, which indicates that the motion in the first subframe havingtiming diagram 754 is faster than the motion in the first subframehaving timing diagram 752.

As shown, the timing diagram 750 for the second subframe includes threeupdates which cause the row to emit light for three intervals 758 a, 758b, and 758 c following the times 756 a, 756 b, and 756 c, respectively.As this second subframe contains no or very slow motion, the duty cyclefor the EL emitters within this row is 100% and the EL emitters aredriven to emit light for the entire available time. Therefore, the ELelements are driven at a relatively low peak luminance as the human eyeintegrates the light output over the entire time. Because there is no orlittle motion, the fact that the human eye integrates this light overthe entire time causes little or no motion blur on the human retina andthe image produced by this row of EL emitters appears sharp.

Similarly, the timing diagram 752 is shown for one of the firstsubframes, where the first subframe is input at a rate equal to the rateof the second subframes and therefore this timing diagram also includesthree updates which cause the row to emit light for three intervals 760a, 760 b, and 760 c following times 756 a, 756 b, and 756 c,respectively. As this first subframe contains faster motion than thesecond subframe, the duty cycle for the EL emitters within this row isless than 100% and is depicted to be approximately 75%. So that the timeintervals 760 a, 760 b and 760 c where the EL emitters are activatedoccupy a larger % of time compared to the time intervals 766 a, 766 b,and 766 c during which the EL emitters are deactivated. That is the ELemitters are driven to emit light for 75% of the available time betweenthe times that the first subframes are input. As a result, the ELelements are driven at a higher peak luminance for the same input imagesignal than the EL elements within a row of the second region as thehuman eye integrates this light over the entire time interval eventhough light is present for 75% of the time. Because the light pulse isshorter than for the second subframe, the amount of blur present on thehuman retina as the user tracks an object in the motion across this rowis reduced and even though motion is present within this first region,the image appears relatively sharp to the user.

The timing diagram 754 is shown for another of the first subframes, thisfirst subframe having a motion rate indicator indicating faster motionthan the first subframe corresponding to timing diagram 752. Once again,the first subframe is input at a rate equal to the rate of the secondsubframes and therefore this timing diagram also includes three updates,which cause the row of EL emitters to emit light for three intervals 764a, 764 b, and 764 c following times 756 a, 756 b, and 756 c,respectively. As this first subframe contains faster motion than thefirst subframes having the timing diagram 752, the duty cycle for the ELemitters within this row is reduced further. As shown, the on-times 764a, 764 b, and 764 c are about equal in time to the time intervals 766 a,766 b, and 766 c during which the EL emitters are deactivated, providinga 50% duty cycle. Once again, the EL elements within this first regionare driven at a higher peak luminance for the same input image signalthan the EL elements within a row of the second region or a row of afirst region having a motion rate indicator which indicated slowermotion as shown in 752, as the human eye still integrates this lightover the entire time interval (represented by 764 a+766 a for example)to determine luminance even though light is present for 50% of the time.Because the light pulse is even shorter, the amount of blur present onthe human retina as the user tracks an object in the video across thisrow is further reduced and even though more rapid motion is presentwithin this first region, the image appears relatively sharp to theuser.

A detailed method for achieving this method is provided in FIG. 12 foran embodiment of this method wherein each row of data in the input videois preceded by a one-bit motion rate indicator, which indicates whethereach row does or does not correspond to a region of the original scenewhich contains rapid motion. As shown in FIG. 12, a motion rateindicator is received in Step 800 and stored in Step 802. A row of imagedata is then received in Step 804. This row of image data is convertedto linear intensity in step 806. A motion rate indicator scalar is thencomputed in Step 808. In one embodiment of the present invention, themotion rate indicator includes a small number of bits, e.g. 1, with eachhigher binary value of the motion rate indicator indicating fastermotion. The corresponding motion rate indicator scalar can be computedby simply adding 1 to the motion rate indicator. Note that in thepresent example, this results in a scalar of 1 if the motion rateindicator is 0, indicating the lack of fast motion and a scalar of 2 ifthe motion rate indicator is 1, indicating the presence of fast motion.The linear intensity values are then multiplied by this motion rateindicator scalar in Step 810 to provide scaled linear intensity values.A row of the display is then selected in step 812 corresponding to thespatial location of the row of image data and the scaled linearintensity values are used to provide data to the display in Step 814.The row is then deselected in Step 816. The motion rate indicator for arow a half frame earlier in the display is then retrieved and determinedwhether the motion rate indicator is set in Step 818. If it is not set,indicating the lack of fast motion for that row, the process returns toStep 800 and the next motion rate indicator is received. If this motionrate indicator is set, the row a half frame earlier is selected in Step820, the signal is removed from this row by sinking the current from thecapacitors in the row in Step 822, the row is deselected in Step 824 andthe data signal is reset in Step 826. This step turns off the earlierrow half way through the update cycle if that row corresponded to aregion with fast motion. The process then returns to Step 800 where thenext motion rate indicator is received and the process is repeated.

Although the previous discussion provides a detailed example, thismethod includes the basic steps shown in FIG. 13. These includereceiving motion rate indicators corresponding to regions of a videosignal in Step 830, receiving the video signal in Step 832, scaling thevideo signal as a function of the motion rate indicator in Step 834,providing the data to the display in Step 836 and adjusting the displayduty cycle in response to the motion rate indicator in Step 838. Assuch, the method includes providing a different display duty cycle forthe first and second regions of the display as differentiated by themotion rate indicator. This method is particularly useful when the firstupdate rate is faster than the second update rate. Regions with no orrelatively slow motion are only updated as new subframes becomeavailable, e.g. once per frame time or less, and regions with relativelyfast motion are updated twice: once to allow light to be emitted inresponse to a new subframe and once to extinguish the light as afunction of the motion rate indicator. In this system, the first updaterate is greater than the first input rate by the fact that regions withfaster motion are updated twice (activation and deactivation) for eachnew subframe.

The motion rate indicators can be used in other ways according themethod of the present invention. For example, when the first subframesare defined in terms of motion rate indicators, the system can produceadditional first subframes using the first subframes or the secondsubframes and then provide additional first subframes to the firstregion of the display to permit the first update rate for the firstregion to be higher than the second update rate for the second region.That is, the controller 602 in FIG. 5 can respond to the motion rateindicator to identify where rapid motion is occurring and produceadditional first subframes for these regions by interpolating new firstsubframes between the first or second subframes at a rate that relatesto the speed of motion present. Methods for producing interpolatedimages between captured images such as optical flow are well known inthe industry, U.S. Pat. No. 7,342,963 describes such a method, whichincludes a forward motion estimation step includes determining a set ofmotion vectors associated with the vertices of a mesh representing afirst image at an instant t1, and enabling the constructing of a meshassociated with a second image at a subsequent instant t2, and a stepfor the constructing of an intermediate image from said approximatepreceding image. An embodiment of the present invention usesinterpolation between frames to produce additional first subframes at arate that relates to the speed of motion present in the video of thescene. In the above embodiments, the video of a scene is carried in avideo signal e.g. NTSC, ATSC, SMPTE 292, MPEG-4, or other signals knownin the video art. However, the video of a scene can be provided througha sequence of still images (e.g. JPEG or MNG as known in theimage-processing art) or other methods. Most commonly-defined videosignals have an active image region and a blanking region, wherein theblanking region permits time for the display to reset. Image data iscommonly provided during the active image region but not during theblanking region. In some embodiments of the present invention, the firstsubframes can be provided without requiring much additional bandwidth.This is particularly true when these subframes are defined through theuse of motion vectors or a motion map, or motion rate indicators such ascapture rate indicators or exposure time indicators. When the firstsubframes require less bandwidth than the available bandwidth in theblanking region of the video signal, the first subframe data can becarried in the blanking region of the video signal. Such first subframesgenerally require less bandwidth than the second subframes, as theblanking region of a video signal is generally lower-bandwidth than theactive image region of the video signal. Note that “bandwidth” and“bit-rate” are used interchangeably here to denote the amount of datawhich can be transferred in a given amount of time.

When the first subframes require low bandwidth compared to the secondsubframes, e.g. because the first subframes have a smaller number ofpixels than the second subframes, the first subframe data can be carriedin the active image region by embedding this information in the activeimage region invisibly to a viewer. In one embodiment of the presentinvention, a method of watermarking, such as that set forth incommonly-assigned U.S. Pat. No. 6,044,182 to Daly et al., can be used toextract the first subframe data. As set forth in this reference, adecoding carrier image can be selected, preferably identical to anencoding carrier used when producing the video of the scene. Thedecoding carrier image can be e.g. a linear or log chirp rotated arounda centerpoint. The data in the active image region can include anembedded frequency dispersed data image carrying the first subframedata. To extract the frequency dispersed data image, the data in theactive image region can be cross-correlated with the decoding carrierimage. The data in the active image region which are most highlycorrelated with the decoding carrier image can be extracted andnormalized to produce the frequency dispersed data image. The locationsof data centers within the frequency dispersed data image can then bedetermined by finding the rows and columns of the cross-correlationresult with the widest data ranges. The values of the cross-correlationresult at the data centers can then be compared to a selected thresholdvalue, e.g. 127.5 on a 0-255 scale, to determine which bits are −1 (e.g.below the threshold), which correspond to binary 0, and which are 1(e.g. above the threshold). The resulting map of 0s and is can beconverted to a linear binary message by e.g. a raster scan. The binarymessage can include digital data, an identification code containing aseries of bits that does not occur in the digital data, orerror-correction bits. According to the present invention, the binarymessage can be coded in 4b5b code as known in the telecommunicationsart, and a 4b5b value not corresponding to a valid four-bit data stringcan be used as the identification code.

According to the present invention, the data in the active image regioncan carry the second subframe data and the first subframe data. Theextracted binary message holds the first subframe data. For example, ifthe first subframe data is motion rate indicators, the bits of thebinary message can be the bits of a binary representation of the motionrate indicators described above.

Other methods can also be used to reduce the bandwidth of the videosignals of the present invention. For instance, it is known that thehuman visual system has limited spatial and temporal bandwidth inchrominance channels as compared to luminance channels. Therefore, it ispossible to reduce the bandwidth, especially for the first subframes, bypermitting these subframes to carry primarily luminance data with littleor no chrominance data. Image processing methods known in the art canthen be used to interpolate the chrominance information from the secondsubframes to provide adequate chrominance information for the firstsubframes.

In one embodiment, the video of a scene is captured by an image capturedevice that detects relative speed of motion of scene regions withrespect to each other. This can include, for example, a method asdisclosed in the above-referenced commonly-assigned U.S. patentapplication Ser. No. 12/401,633. An image capture device according tothis reference can detect areas of fast motion in the scene and providefirst subframe data at a first capture rate corresponding to those areasof fast motion, in addition to second subframe data at a second capturerate less than the first capture rate corresponding to areas of thescene which do not contain fast motion. According to the presentinvention, the first and second subframes produced by the image capturedevice are received and displayed to provide reduced motion blur. In apreferred embodiment, the invention is employed in a display thatincludes Organic Light Emitting Diodes (OLEDs), which are composed ofsmall molecule or polymeric OLEDs as disclosed in but not limited toU.S. Pat. No. 4,769,292, by Tang et al., and U.S. Pat. No. 5,061,569, byVanSlyke et al. Many combinations and variations of organic lightemitting materials can be used to fabricate such a display. Otherdisplay technologies, including liquid crystal, plasma, projection,reflective or field emissive display technologies, can also be employedin the present invention.

The invention has been described in detail with particular reference tocertain preferred embodiments thereof, but it will be understood thatvariations and modifications can be effected within the spirit and scopeof the invention.

PARTS LIST

-   -   10 a-c pulse signifying initiation of update for second regions    -   20 a-g pulse signifying initiation of update for first regions    -   30 a-i pulse signifying initiation for an update for first        regions    -   42 receive video signal step    -   44 determine subframe type step    -   46 select first row step    -   48 provide data step    -   50 deselect row step    -   52 remove data step    -   54 determine all rows updated step    -   56 select subsequent row step    -   58 determine region location step    -   60 process data step    -   62 select first row step    -   64 provide data step    -   66 deselect row step    -   68 remove data signal step    -   70 determine all rows in region updated step    -   72 select subsequent row step    -   82 receive video signal step    -   84 determine subframe type step    -   86 write second subframe to memory step    -   88 determine region location step    -   90 process data step    -   92 select region step    -   94 write first subframe to memory step    -   100 display    -   110 a, 110 b second region    -   120 first region    -   200 provide video image data step    -   210 provide subframes to first region step    -   215 update first region step    -   220 provide subframes to second region step    -   225 update second region step    -   230 user observes displayed video image step    -   300 image region    -   310 location of moving object in first frame    -   320 location of moving object in second frame    -   330 motion vector    -   340 timing diagram for second subframes    -   345 timing diagram for first subframes    -   350 timing diagram for first subframes    -   360 a-c onset for second subframes    -   370 a-g onset for first subframes    -   380 a-c onset for first subframes    -   600 display system    -   602 controller    -   604 video signal    -   606 signal    -   608 first row driver    -   610 signal    -   612 column drivers    -   620 second row driver    -   622 signal    -   624 memory    -   630 second region of the display    -   634 first region of the display    -   700 a-e first subframes    -   702 a-b second subframes    -   704 a-e region location data    -   710 portion of active matrix backplane    -   711 capacitor line    -   712 select lines    -   714 select TFT    -   716 data line    -   718 capacitor    -   720 power TFT    -   722 power line    -   724 electrode    -   740 a-i on time for row in first region    -   742 a-i off time for row in first region    -   744 a-e on time for row in second region    -   746 timing diagram for row in first region    -   748 timing diagram for row in second region    -   750 timing diagram for row in second region    -   752 timing diagram for row in a first region    -   754 timing diagram for row in a first region    -   756 a-d time for delivery of subframe data    -   758 a-c on time for row in second region    -   760 a-c on time for row in a first region    -   762 a-c off time for row in a first region    -   764 a-c on time for row in a first region    -   766 a-c off time for row in a first region    -   800 receive motion rate indicator step    -   802 store motion rate indicator step    -   804 receive row of image data step    -   806 convert to linear intensity step    -   808 calculate motion rate indicator data step    -   810 multiply step    -   812 select row step    -   814 provide data step    -   816 deselect row step    -   818 determine previous motion rate indicator step    -   820 select earlier row step    -   822 sink data step    -   824 deselect row step    -   826 reset data signal step    -   830 receive motion rate indicator step    -   832 receive video signal step    -   834 scale video signal step    -   836 provide signal step    -   838 adjust duty cycle step

What is claimed is:
 1. A method comprising: receiving a video of a scenehaving first subframes that have a first input rate and second subframesthat have a second input rate less than the first input rate, whereinthe first subframes correspond to a first region of a display and thesecond subframes correspond to a second region of the display, andwherein the received video includes motion rate indicators; determininga first update rate and a second update rate based at least on themotion rate indicators; and selectively providing the first and secondsubframes to corresponding regions in the display, and providing thefirst region of the display with the first update rate and the secondregion of the display with the second update rate, wherein the firstupdate rate is greater than the second update rate, such that thedisplayed image has reduced motion blur.
 2. The method of claim 1,wherein the motion rate indicators include exposure rate indicators. 3.The method of claim 1, wherein the motion rate indicators includecapture rate indicators corresponding to frequency of scene captures perunit time.
 4. The method of claim 1, wherein the motion rate indicatorsinclude a motion map indicating, for each pixel or region of eachsubframe, how an image in the pixel or region moves between consecutiveframes.
 5. The method of claim 1, wherein selectively providingincludes: producing additional first subframes using the first subframesor the second subframes; providing the additional first subframes to thefirst region of the display.
 6. The method of claim 1, wherein the videois captured by an image capture device that detects relative speed ofmotion of scene regions with respect to each other.
 7. The method ofclaim 1, wherein the video of the scene is carried in a video signal. 8.The method of claim 7, wherein the video signal has an active imageregion and a blanking region and wherein first subframe data are carriedin the blanking region and second subframe data are carried in theactive image region.
 9. The method of claim 7, wherein the video signalhas an active image region and wherein the second subframe data arecarried in the active image region and the first subframe data arecarried in a frequency dispersed data image in the active image region.10. The method of claim 1, wherein the video image data includes: firstsubframes for a first area of the video image of the scene associatedwith rapid motion, wherein the first subframes has a first input rate,and second subframes for a second area of the video image of the scene,wherein the second subframes have a second input rate less than thefirst input rate.
 11. The method of claim 10, wherein the video isreceived from a transmission system, wherein bandwidth of thetransmission system is insufficient to transmit the selected resolutionat the selected frame rate but is sufficient to transmit the first andsecond subframes; and at least two of the second subframes of the videoimage data includes a feature within the video image data that movesbetween the at least two of the second subframes.
 12. A systemcomprising: an interface configured to receive the video having firstsubframes that have a first input rate and second subframes that have asecond input rate less than the first input rate, wherein the firstsubframes correspond to a first region of a display and the secondsubframes correspond to a second region of the display, and wherein thereceived video includes motion rate indicators; a processor configuredto: determine a first update rate and a second update rate based atleast on the motion rate indicators; and present the first and secondsubframes to corresponding regions in the display, and to present thefirst region of the display with the first update rate and the secondregion of the display with the second update rate, wherein the firstupdate rate is greater than the second update rate, such that thedisplayed image has reduced motion blur; and an image capture deviceconfigured to capture video and to detect relative speed of motion ofscene regions with respect to each other.
 13. The system of claim 12,wherein the image capture device is configured to provide motion rateindicators along with the captured video to the interface.
 14. Thesystem of claim 12, wherein the video of the scene is carried in a videosignal and wherein the video signal has an active image region and ablanking region and wherein first subframe data are carried in theblanking region and second subframe data are carried in the active imageregion.
 15. The system of claim 12, wherein the video of the scene iscarried in a video signal and wherein the video signal has an activeimage region and wherein the second subframe data are carried in theactive image region and the first subframe data are carried in afrequency dispersed data image in the active image region.
 16. Thesystem of claim 12, wherein the video image data includes: firstsubframes for a first area of the video image of the scene associatedwith rapid motion, wherein the first subframes has a first input rate,and second subframes for a second area of the video image of the scene,wherein the second subframes have a second input rate less than thefirst input rate.
 17. The system of claim 16, further comprising atransmission system configured to receive the video, wherein bandwidthof the transmission system is insufficient to transmit the selectedresolution at the selected frame rate but is sufficient to transmit thefirst and second subframes; and at least two of the second subframes ofthe video image data includes a feature within the video image data thatmoves between the at least two of the second subframes.
 18. An apparatuscomprising: means for receiving a video of a scene having firstsubframes that have a first input rate and second subframes that have asecond input rate less than the first input rate, wherein the firstsubframes correspond to a first region of a display and the secondsubframes correspond to a second region of the display, and wherein thereceived video includes motion rate indicators; means for determining afirst update rate and a second update rate based at least on the motionrate indicators; and means for selectively providing the first andsecond subframes to corresponding regions in the display, and forproviding the first region of the display with the first update rate andthe second region of the display with the second update rate, whereinthe first update rate is greater than the second update rate, such thatthe displayed image has reduced motion blur.
 19. The apparatus of claim18, wherein the motion rate indicators include capture rate indicatorscorresponding to frequency of scene captures per unit time.
 20. Theapparatus of claim 18, wherein the motion rate indicators include amotion map indicating, for each pixel or region of each subframe, how animage in the pixel or region moves between consecutive frames.